RU40593U1 - DEVICE FOR COMPLEX MAGNETO-LASER THERAPY - Google Patents

Abstract

The utility model relates to medical equipment, namely, devices for physiotherapeutic effects on the body of physical factors (in particular, laser radiation of the infrared wavelength range and artificial magnetic fields) in experimental studies and clinical practice. A device for complex magnetic laser therapy is proposed, which contains a PMD source having a ring shape, an optical emitter with an ICLI source, equipped with an additional BPeMP magnetic emitter located between the optical emitter and the PMP source in such a way that the ICLI, BPeMP and PMP sources have a common axis. An optical emitter containing an ICLI source and an annular PMF source are mounted on the housing of the BPeMP magnetic emitter with the possibility of moving them relative to the housing of the BPeMP magnetic emitter, the PMP source being oriented by the north magnetic pole in the direction of laser radiation propagation.

Description

The utility model relates to medical equipment, namely, devices for physiotherapeutic effects on the body by physical agents (in particular, laser radiation and artificial magnetic fields) in experimental studies and clinical practice.

A known apparatus for magnetic laser therapy, designed for combined physiotherapeutic effects of light radiation of the infrared wavelength range and a constant magnetic field in experimental and clinical medicine. The apparatus contains a control unit, a terminal with laser radiation sources (LI) and an LED matrix, a constant magnetic field source made in the form of parallelepiped-like magnets, covering the terminal aperture in the shape of a square, while the near ends of the magnets located perpendicular to each other are opposite-pole [1] . A device of this design can improve the effectiveness of the combined therapeutic effects of electromagnetic fields on the human body.

However, the functionality of the described device, not possessing the combined properties of the applied physical agents, is limited to the combined use of low-energy light radiation in the infrared (IR) region of the spectrum (coherent laser - ICLI or incoherent - LEDs) and energy

source of constant magnetic field (PMF). The latter does not have its own therapeutic properties, but forms in the tissue structures of the body collinear-preferred directions of the propagation of light radiation and contributes to the resonant interaction of biological structures [2]. Due to the fact that resonance-orientational effects due to PMF reduce the influence of the Tyndall effect on the scattering of light radiation, the radiobiological effects arising in the tissues of the body subjected to irradiation are more associated with direct absorption of electromagnetic (EM) radiation energy than with losses scattering it [3].

The main disadvantage of the analogue is the low therapeutic effect when using physical agents of the same nature - light radiation (ICLI) and LEDs. Passing through tissues, LI changes its physical properties, first of all, losing coherence, therefore the nature of the therapeutic effect on the cavity tissues of the body is determined only by a single parameter - radiation monochromaticity [4]. Therefore, the combined use in the design of an analogue of low-energy (coherent - laser and incoherent - LEDs) radiation in the IR region on the one hand does not represent a significant gain in therapeutic effects, on the other hand, there is no possibility of the influence of EM radiation on the cavity organs and tissue structures of the body due to a change in parameters PMP. Rigid binding of PMF sources with respect to light emitters does not allow efficient control

the depth of penetration of radiation energy into the body tissue without losing a certain fraction of it due to the spatial distribution of the magnetic field lines of the parallelepiped-like permanent magnets, covering the square aperture of the terminal, heterogeneous in the corners of the square, in contrast to the homogeneous distribution of the field of the ring-shaped magnet uniformly covering the ICLI cone .

As a prototype, a device for cavity magnetic laser therapy [5], intended for use in clinical and outpatient practice, containing a laser emitter of the IR range and a permanent magnet as acting physical agents of an electromagnetic nature, was selected. The design of this device provides:

- the location of the LEDs and the laser in the same plane in contact with the optically transparent hygienic surface of the phonendoscope membrane;

- increase the area of the ring magnet, improving the functionality of the device.

The disadvantages of the above construction, in addition to those examined by the example of an analogue, include a limited set of EM radiation sources that do not allow the use in the treatment of diseases, in particular, the gastroenterological profile, of physical agents possessing a phoretic (transmembrane ionic transfer of drugs using low-frequency magnetic fields moving in space) effects on the body. Alternating magnetic fields [6], which synergistically combine with LI and **********, possess similar properties.

they are more effective for complex use, in contrast to the single treatment of chronic gastritis with LI alone [7] or LED matrix radiation [8].

We were the first to propose a device for complex magnetic laser therapy containing a PMD source, having the shape of a ring, an optical emitter with an ICLI source, equipped with an additional BPeMP magnetic emitter located between the optical emitter and the PMP source in such a way that the ICLI, BPeMP and PMP sources have a common axis. An optical emitter containing an ICLI source and an annular PMF source are mounted on the BPeMP emitter body with the possibility of moving them relative to the latter, the PMF source being oriented by the north magnetic pole in the direction of laser radiation propagation.

The values of the area of the irradiated surface of the skin, the projection of the internal organs of the macroorganism or puncture subjected to complex magnetic laser exposure, depend on the change in the position of the ICLI laser emitter relative to the body of the magnetic emitter BPeMP. A change in the position of the PMF source relative to the body of the magnetic emitter BPeMP varies the depth of penetration of physical agents during magnetic cavity therapy.

Figure 1 presents the design of the proposed device, where:

1 - the case of the device for integrated magnetic laser therapy;

2 - magnetic emitter BPeMP;

3 - source of PMP in the form of a ring;

4 - laser emitter ICLI;

5 - a device for moving a laser emitter relative to the body of the magnetic emitter BPeMP;

6 - a device for moving an annular magnet relative to the housing of the magnetic emitter BPeMP.

The device operates as follows: due to the interference (interfering) nature of the EM fields of the ICLI laser emitter (4) and the BPeMP magnetic emitter (2), a zone of complex magneto-laser exposure arises. The size (diameter) of this zone and, accordingly, the energy parameters of the ICLI at a certain pulse repetition rate, are controlled by the moving device (5) of the ICLI laser emitter (4) relative to the housing of the magnetic emitter BPeMP (2). When combining the planes of both emitters (touching the skin), the diameter of the irradiated zone of the order of 1.5 ÷ 2.5 mm is used to puncture the skin of the patient's body (magnetolaser puncture). When lifting the ICLI laser emitter (4) by means of a displacement device (5) relative to the case of the BPeMP magnetic emitter (2), the diameter of the irradiated zone changed from 60 mm (with a divergence angle of the PI cone of 30 °) to the diameter of the zone of 20 mm (when lifting the laser ICLI emitter (4) to a height of 35 mm relative to the latter). PMP source (3) in the form of a ring mounted on the outer cylindrical surface of the magnetic emitter BPeMP (2) and facing the north pole

in the direction of propagation of laser radiation, is intended to change the depth of distribution of physiotherapeutic agents in the patient's body. The field strength of the PMF source (3) varied with respect to the irradiated surface within 50--5 mT when the ring magnet was moved by the device (6) by 5--35 mm relative to the housing of the BPeMP magnetic emitter (2). This ensured optimal conditions for the activation of metabolic processes, which were a direct consequence of the complex magnetolaser action (IULI and BPeMP) in the presence of a PMP collinear to them. Electrophysiological, magnetobiological, photochemical and thermogenic processes, resonant effects that increase the role of the biological effect of physical agents on this organ arise in the cells of pathological substrates of a diseased organ subjected to the complex effect of EM fields crossed in space. Structurally, all elements of the device for complex magnetic laser therapy are combined in a housing (1).

The combined effect of EM fields - ICLI and BPeMP in the presence of collinear PMF with the orientation of the north magnetic pole of the PMF source in the direction of laser radiation propagation, used in the physiotherapeutic treatment of gastroenterological diseases, reduced the exposure time by four times compared with single treatment of chronic gastritis (by only laser radiation or LEDs). The treatment of gastroduodenal pathology was carried out by means of a complex external magnetic laser effect on

external projection of the antrum of the stomach in the area of severe pain. After a full course of treatment (6 ÷ 10 sessions), there was an improvement in the well-being of patients, the disappearance of pain in the epigastric region, improved appetite, the disappearance of belching, nausea and heartburn. List of references:

1. RU 2134601 C1 Khristoforov V.N., Khristoforova T.V., Grabovshchiner A.Ya. Apparatus for magnetic laser therapy 1993.

2. Bogolyubov V.M., Zubkova S.M. Ways to optimize the parameters of physiotherapeutic effects. // Questions of balneology, physiotherapy and exercise therapy. - 1998. - No. 2. - C.3-6.

3. Tiflova O.A. Bacterial model of the effect of laser radiation on the intensity of cell division // Radiobiology. - 1993.V.33, issue 3. S.323-327.

4. Lobko V.V., Karu T.I., Letokhov B.C. Is the coherence of low-intensity laser light significant when exposed to biological objects? Biophysics. 1985. Volume XXX, issue 2. S.366-371.

5. RU 2061512. Grin V.N. Device for magnetic laser therapy. 1991.

6. Briskin B.S., Polonsky A.K., Aliev I.M. and others. Magnetic laser irradiation of the liver in the treatment and prevention of liver failure in obstructive jaundice. // Surgery. - 1991. - No. 2. - S. 73-74.

7. Osadchuk M.A., Goremykin V.I., Kozlova N.V. Gastroenterology. Part 1. Saratov. Publishing House of Saratov Honey. University. 1998. S. 352-354.

8. RU 2051664 Shustov L.P., Kharlamova T.I., Kritskaya N.G. et al. A method for the treatment of chronic gastritis. 1989.

Claims (1)

A device for complex magnetic laser therapy, comprising a housing, an optical emitter containing a source of infrared laser radiation (ICLI) and a source of constant magnetic field (PMF) in the form of a ring, characterized in that it is additionally equipped with a magnetic emitter of a traveling alternating magnetic field (BpeMP) located between the optical emitter and the PMF source so that the sources of the ICLI, BPeMP and PMP have a common axis, and the optical emitter containing the source of the ICLI and the PMF source in the form of a ring, updated on the case of the emitter BPeMP with the ability to move relative to the latter, and the PMF source is oriented by the north magnetic pole in the direction of laser radiation propagation.